1. Vision I.Introduction II.The Nature of Light III.Anatomy of the Visual System IV.Analysis of Visual Information in the Retina V.Analysis of Visual Information in the Cortex

2. I. Introduction Sensation: the process of converting physical energies into the language of the brain. Accomplished by sensory receptors (specialized neurons) that perform transduction (or translation) These receptors show receptor potentials (gradual voltage shifts) instead of action potentials

3. II. The Nature of Light

5. III. Anatomy of the Visual System

7. Blind Spot

10. The Fovea

11. Blue= rods Green = Cones

15. Pathways from the Retina In the brain, retinal ganglion axons travel to… – the lateral geniculate nucleus (LGN) and then the primary visual cortex (V1, area 17): more to come… – the hypothalamus: control bodily/circadian rhythms – the tectum (superior colliculi), pulvinar (thalamus), and then visual association cortex: orienting eyes to things we see and hear

18. Retinal ganglion cell axons synapse with three types of neurons in the LGN Magnocellular layer (M layer) has larger cell bodies – Layers 1 & 2 – Process information related to form, movement, depth, small changes in brightness – Connected mostly with rods Parvocellular layer (P layer) has smaller cell bodies – Layers 3 through 6 – Process information related to color and fine detail – Connected mostly with cones Koniocellular layer – Connected mostly with blue cones

19. The Retinotopic Map There is a distorted map of our retina (which registers the visual world) at several different places in the brain Each place in our visual field is represented by the activity of particular neurons in several different parts of our visual system This map of the retina is represented and maintained in the LGN, primary visual cortex (V1), and other visual processing areas – Distinction of M and P layers started in the LGN is maintained in V1 as well

21. IV. Analysis of Visual Information in the Retina

23. Receptive Field Example

27. +

35. V. Analysis of Visual Information in the Cortex

36. Aspects of Vision Processed in the Primary Visual Cortex (V1) Orientation and Movement Spatial Frequency and Texture Retinal disparity/binocular disparity Color NOTE: all functions appear to be processed by distinct sets of V1 neurons

38. Feature Detector

39. Modular Organization of V1 V1 appears to be organized into modules Each module receives input from both eyes about one small part of the visual field Input from each eye is separated into “ocular dominance columns” within the module CO Blobs: color and low spatial frequency Outside of CO Blobs: orientation, movement, spatial frequency, texture, binocular disparity

42. V. Analysis of Visual Information in the Cortex

43. Visual Association Cortex (areas outside of V1) Dorsal Stream – Projects from just outside V1 to the parietal lobe – Helps us to figure out where things are – Often called the “where” or “how” pathway Ventral Stream – Projects from outside of V1 to the temporal lobe – Involved in identifying what we see – Often called the “what” pathway

47. Sleep and Biological Rhythms I.Introduction II.Measuring Sleep III.Stages of Wakefulness and Sleep IV.Why Do We Sleep? V.Physiological Mechanisms of Sleep VI.Biological Clocks

48. I. Introduction

49. II. Measuring Sleep EEG EMG EOG

52. Dolphin Brain during Sleep

53. Neurotransmitters Involved in Arousal NorepinephrineLocus coeruleous (pons) AcetylcholineBasal forebrain and reticular formation (in pons and medulla) SerotoninRaphe nuclei (pons and medulla) HistamineTuberomammillary nucleus (hypothalamus) Orexin (Hypocretin)Hypothalamus

54. Neural Control of Slow-Wave Sleep Ventrolateral preoptic area (basal forebrain, in front of the hypothalamus; vlPOA) Destruction -> insomnia, coma, & death Injection of adenosine into the basal forebrain produces sleep Sleep promoting brain area of the Sleep/Waking Flip-Flop (Sleep ON neurons)

55. Sleep/Waking Flip-Flop

57. Neural Control of REM Sleep REM ON region: sublaterodorsal nucleus (SLD) located in the dorsal pons REM OFF region: ventolateral periaqueductal gray matter (vlPAG) located in the midbrain These two structures make up the REM Sleep Flip-Flop

58. REM Sleep Flip-Flop

60. The Suprachiasmatic Nucleus (SCN)

61. The “Ticking” of the Circadian Clock Involves the cycling of proteins (such as Per, Cry & Tim) inside of SCN neurons The proteins rise and fall in a pattern that repeats about every 24 hours Demo

62. Reproductive Behavior I.Sexual Development II.Hormonal Influence of Sexual Behavior III.Neural Influence of Sexual Behavior

63. I. Sexual Development

64. Gametes Almost all cells of the human body contain 23 pairs of chromosomes (46 Total) in their nuclei Gametes (sperm and ova) have 23 individual chromosomes in their nuclei (23 Total)

66. Human Chromosomes

67. Sex Chromosomes

69. Organizational Effects Hormone effect that directly changes tissue differentiation and/or development Causes changes in structures of the organism Organizational effects occur early in development Not reversible

70. Activational Effects Effect of a hormone on the fully developed (or mature) organism Act on pre existing structures, causing some type of change Activational effects often depend on prior organizational effects Examples: changes to boys and girls with puberty, ovulation in women

72. Primordial Gonads (bipotential or bisexual) Genetic Females (XX)  No SRY gene Genetic Males (XY) SRY gene makes testis determining factor  Gonads become ovariesGonads become testes No testicular hormonesTesticular hormones (anti-Müllerian hormone & androgens)  Müllerian System Develops (feminization) Wolffian System Withers (demasculinization) Müllerian System Withers (defeminization) Wolffian System Develops (masculinization)

73. Sexual Differentiation Disorders/Intersexuality Androgen Insensitivity Syndrome (AIS) Persistent Müllerian Duct Syndrome Congenital Adrenal Hyperplasia (CAH) Turner’s Syndrome

74. Genetic male with AIS

75. II. Hormonal Influence on Sexual Behavior

76. Puberty

77. Activational Effects of Sex Hormones at Puberty (See Figure 9.5 in Text) HYPOTHALAMUS secretes: GnRH (Gonadotropin Releasing Hormone)  ANTERIOR PITUITARY secretes: gonadotropic hormones (FSH & LH)  GONADS Secrete: sex steroids  OVARIES Secrete: estradiol (some testosterone) TESTES Secrete: testosterone (some estradiol)  hips widen, breast develop, and other changes facial hair, voice drops, and other changes

78. Sexual Orientation

79. Genetic Females Money et al. (1984) asked about sexual orientation of women with CAH – 37% homosexual/bisexual – 40% exclusively heterosexual – 23% refused to answer Kinsey Report (1943) data on sexual experience with another woman – 10% overall – 40% of women with prenatal androgen exposure

80. Genetic Females Goy et al. (1988) exposed developing female primates to androgens – As adults, these primates showed more male- typical behaviors

81. Genetic Males Androgen Insensitivity Syndrome – Behavior is often stereotypically feminine – Most are sexually attracted to men – They marry men and have average sex lives

82. Sexual Orientation & the Brain Sexual dimorphisms: brain area of behavior is different between the sexes Possible dimorphisms related to sexual orientation: – Two parts of the hypothalamus (the SCN and the INAH-3) – Anterior commissure

83. Heredity & Sexual Orientation Concordance rates for homosexuality among twins: Identical Twins (MZ)Fraternal Twins (DZ) Males52%22% Females48%16%

84. III. Neural Influence on Sexual Behavior

85. Male Rat Medial Preoptic Area (MPA) – Controls sexual behavior (mounting and pelvic thrusting) Medial Amygdala – Influences sexual motivation

86. Sexually Dimorphic Nucleus (SDN) of the Medial Preoptic Area (MPA)

88. Female Rat Ventromedial Hypothalamus (VMH) Controls sexual behavior (lordosis)